近三年发表论文 (一作及通讯)
2022年
[26] Mingyang Yang, Mengxuan Zhao, Ji Yuan, Junxuan Luo, Zhouguang Lu, Dazhu Chen, Xianzhu Fu, Lei Wang, Chen Liu*, Oxygen vacancies and interface engineering on amorphous/crystalline CrOx-Ni3N heterostructures toward high-durability and kinetically accelerated water splitting, Small, 2022. (IF=13.281)
[25] Chen Liu*, Fangyan Zhu, Zhonghan Huang, Wenchao Liao, Xiang Guan, Yuchao Li, Dazhu Chen*, Zhouguang Lu*, An integrate and ultra-flexible solid-state lithium battery enabled by in situ polymerized solid electrolyte, Chemical Engineering Journal, 2022, https://doi.org/10.1016/j.cej.2022.134644 (IF=13.273)
The flexible solid-state battery was achieved by employing an ultra-flexible and shape conformable PEL electrolyte which was in situ polymerized on cathode. The PEL with good interfacial compatibility with cathode and excellent stability against Li anode enables the integrated solid-state lithium battery with superior cycling performance at 25 °C, 40 °C and 60 °C.
[24] Rong Fan, Wenchao Liao, Shuangxian Fan, Dazhu Chen, Jiaoning Tang, Yong Yang, Chen Liu*, Regulating interfacial li-ion transport via an integrated corrugated 3D skeleton in solid composite electrolyte for all-solid-state lithium metal batteries, Advanced Science, 2022, 2104506. (IF=16.806)
A corrugated 3D nanowires-bulk ceramic-nanowires skeleton reinforced composite electrolyte is designed with fast Li ion transfer kinetics and to solve the Li+ concentration polarization at electrode/electrolyte interface, thereby eliminating the energy barrier originated from the redistribution of charge carriers and offering homogeneous interfacial Li ion flux on lithium anode.
[23] Zhiyu Ding, Qiming Tang, Yanchen Liu, Penghui Yao, Chen Liu*, Xingjun Liu*, Junwei Wu*, Marino Lavorgna, Integrate multifunctional ionic sieve lithiated X zeolite-ionic liquid electrolyte for solid-state lithium metal batteries with ultralong lifespan, Chemical Engineering Journal, 2022, https://doi.org/10.1016/j.cej.2021.133522 (IF=13.273)
2021年
[22] Kangqiang He#, Samson Ho-Sum Cheng#, Jieying Hu#, Yangqian Zhang, Huiwen Yang, Yingying Liu, Wenchao Liao, Dazhu Chen, Chengzhu Liao, Xin Cheng, Zhouguang Lu, Jun He, Jiaoning Tang, Robert K.Y. Li, Chen Liu*, In-situ intermolecular interaction in composite polymer electrolyte for ultralong life quasi-solid-state lithium metal batteries, Angewandte Chemie International Edition, 2021, 60, 2-10. (IF=15.336)
The dense interfacial Li+ conduction pathways between garnet fillers and polymer matrix via the open-ring reaction of ethylene carbonate initiated by LiOH/Li2CO3 contaminant on LLZTO is reported, which results in the superior ionic conductivity of composite electrolytes at room temperature and long lifespan of assembled solid-state lithium batteries.
[21] Samson Ho-Sum Cheng, Chen Liu*, Fangyan Zhu, Liang Zhao, Rong Fan, Chi-Yuen Chung, Jiaoning Tang, Xierong Zeng, Yan-Bing He*, (Oxalato)borate: the key ingredient for polyethyleneoxide based composite electrolyte to achieve ultra-stable performance of high voltage solid-stateLiNi0.8Co0.1Mn0.1O2/lithium metal battery, Nano Energy, 2021, 80, 105562. (IF=17.881)
Stable charge-discharge performance of 4V NCM solid-state battery are realized via addition of LiBOB salts to conventional single salt plasticized PEO solid composite electrolyte. Polymer electrolyte decomposition and active materials cracking at high voltage are suppressed by multiplied polymer-ion interactions and formation of stable C-O/Li-B-O containing solid electrolyte interphase, leading to strikingly improvement in capacity retention.
[20] Fangyan Zhu, Samson Ho-Sum Cheng, Yi Xu, Wenchao Liao, Kangqiang He, Dazhu Chen, Chengzhu Liao, Xin Cheng, Jiaoning Tang, Robert K.Y. Li, Chen Liu*, Dual-salt effect on polyethylene oxide/Li6.4La3Zr1.4Ta0.6O12 composite electrolyte for solid-state lithium metal batteries with superior electrochemical performance, Composites Science & Technology, 2021, 210, 108837. (IF=8.528)
The stable solid electrolyte interphase with LiF, B-F, and Li-B-O formed on lithium metal effectively induces even Li deposition and strengthens the compatibility of electrolyte/Li anode interface. The combined action of each composition in the electrolyte guarantees the efficient ion immigration kinetic and suppresses the lithium dendrite growth of solid-state batteries.
[19] Rui Hao, Jingjing Chen, Zhenyu Wang, Junjun Zhang, Qingmeng Gan, Yanfang Wang, Yingzhi Li, Wen Luo, Zhiqiang Wang, Huimin Yuan, Chunliu Yan, Wei Zheng, Yanping Huang, Penggao Liu, Jun Yan, Kaiyu Liu*, Chen Liu*, Zhouguang Lu*, Iron polyphthalocyanine-derived ternary-balanced Fe3O4/Fe3N/Fe-N-C@PC as a high-performance electrocatalyst for the oxygen reduction reaction, SCIENCE CHINA Materials, 2021, https://doi.org/10.1007/s40843-021-1699-4,2021.06. (IF=8.273)
[18] Mingyang Yang, Zhifeng Wang, Hanyu Ben, Mengxuan Zhao, Junxuan Luo, Dazhu Chen, Zhouguang Lu, Lei Wang, Chen Liu*, Boosting the zinc ion storage capacity and cycling stability of interlayer-expanded vanadium disulfide through in-situ electrochemical oxidation strategy, Journal of Colloid and Interface Science, 2022, 607, 68-75. (IF=8.128)
The in-situ electrochemical oxidation of interlayer expanded vanadium disulfide (VS2·NH3) into hydrated vanadium oxide (V2O5·nH2O), delivers highly reversible capacity and improved cycling stability for Zinc ion storage.
[17] Haidong Bian, Zebiao Li, Jie Pan, Fucong Lyu, Xufen Xiao, Jiaoning Tang, Patrik Schmuki, Chen Liu*, Jian Lu*, Yang Yang Li*, Anodic self-assembly method for synthesizing hierarchical FeS/FeOx hollow anospheres, Journal of Power Sources, 2021, 484: 229268. (IF=9.127)
Mesoporous cobalt sulfides (CoSx) were self-grown on the metal substrate via a facile, one-step anodization method for high efficient overall water splitting.
[16] Rui Hao, Jingjing Chen, Zhenyu Wang, Yanping Huang, Penggao Liu, JunYan, Kaiyu Liu*, Chen Liu*, Zhouguang Lu*, Trimetallic Zeolitic imidazolite framework-derived Co nanoparticles@CoFe-nitrogen-dopedporous carbon as bifunctional electrocatalysts for Zn-air battery, Journal of Colloid and Interface Science, 2021, 586: 621-629. (IF=8.128)
[15] Rui Hao, Shuai Gu, Jingjing Chen, Zhenyu Wang, Qingmeng Gan, Zhiqiang Wang, Yanping Huang, Penggao Liu, Kaili Zhang, Kaiyu Liu*, Chen Liu*, Zhouguang Lu*, Microporous Fe-N4 catalysts derived from biomass aerogel for high performance Zn–air battery, Materials Today Energy, 2021, 21, 100826. (IF=7.311)
[14] Haidong Bian , Tongyuan Chen Zhixuan Chen, Jiahua Liu, Zebiao Li, Peng Du , Binbin Zhou, Xierong Zeng, Jiaoning Tang, Chen Liu∗, One-step synthesis of mesoporous Cobalt sulfides (CoSx ) on the metal substrate as an efficient bifunctional electrode for overall water splitting, Electrochimica Acta, 2021, 389:138786. (IF=6.091)
[13] Mingyang Yang#, Chaoqun Shangd#, Feifei Li#, Chen Liu*, Zhenyu Wang, Shuai Gu, Di Liu, Lujie Cao, Junjun Zhang, Zhouguang Lu*, and Hui Pan*, Synergistic electronic and morphological modulation on ternary Co1–xVxP nanoneedle arrays for hydrogen evolution reaction with large current density, Science China Materials, 2021, 64: 880-891. (IF=8.273)
[12] Mengxuan Zhao#, Mingyang Yang#, Weijie Huang, Wenchao Liao, Haidong Bian, Dazhu Chen, Lei Wang, Jiaoning Tang, Chen Liu*, Synergism on Electronic Structures and Active Edges of Metallic Vanadium Disulfide Nanosheets via Co Doping for Efficient Hydrogen Evolution Reaction in Seawater, ChemCatChem, 2021, 13, 1-8. Front cover article. (IF=5.686)
The cover picture shows that cobalt doped metallic vanadium disulfide nanosheets exhibit excellent catalytic performance for hydrogen evolution reaction of seawater electrolysis. Experimentally derived that the doping of cobalt atoms makes vanadium disulfide nanosheets matrix possess numerous exposed active edges and optimized electronic structure. The synergistic effect of active edges and electronic structure of the modified catalyst increases the number of active sites and enhances their intrinsic activity. Therefore, the modified catalyst displays strengthened hydrogen evolution catalytic activity for seawater electrolysis and even shows outstanding long-term stability during electrolysis.
[11] Haobin Yu, Yang Zhang, Leyuan Li, Zhiyu Ding, Yafen Chen, Qunhui Yuan, Ruiting Sun, Kaikai Li*, Chen Liu*, Junwei Wu*, SnO2 nanoparticles embedded in 3D hierarchical honeycomb-like carbonaceous network for high-performance lithium ion battery, Journal of Alloys and Compounds, 2021, 858: 157716. (IF=5.316)
[10] Jia-hua Liu#, Xiao-ying Xu#, Chen Liu*, Da-Zhu Chen*, Thermal effect on pseudocapacitive behavior of high performance flexible supercapacitors based on polypyrrole-decorated carbon cloth electrodes, New Journal of Chemistry, 2021, 45:12435. (IF=3.591)
[9] Wenchao Liao, Chen Liu*, Structural design of composite polymer electrolytes for solid-state lithium metal batteries, ChemNanoMat, 2021, 7: 1-12. Invited review. (IF=3.154)
The review mainly focuses on the impact of the composite electrolyte structure on its ion conduction ability and interfacial compatibility, including physical contact of the electrolyte with electrodes, formation of lithium dendrites and space charge layer, adapting to high-voltage cathode, as well as corresponding solving strategies. Moreover, the structural design-based ion transport mechanism is highlighted, and the inorganic component with 0D, 1D, 2D, 3D and vertical structure are summarized.
2020年
[8] Rong Fan#, Chen Liu#*, Kangqiang He, Samson Ho-Sum Cheng, Dazhu Chen, Chengzhu Liao, Robert K Y Li, Jiaoning Tang, Zhouguang Lu*. Versatile strategy for realizing flexible room-temperature all-solid-state battery through a synergistic combination of salt affluent PEO and Li6.75La3Zr1.75Ta0.25O12 nanofibers, ACS Applied Materials & Interfaces, 2020, 12: 7222-7231. (IF=9.229)
[7] Yang Shi#, Zhibin Yi#, Yanping Kuang, Hanyu Guo, Yingzhi Li, Chen Liu*, Zhouguang Lu*, Constructing stable covalent bonding in black phosphorus/reduced graphene oxide for lithium ion battery anodes, Chemical Communications, 2020, 56, 11613-11616. (IF=6.222)
[6] Venkata Narayana Palakollu, Rajshekhar Karpoormath, Lei Wang, Jiao-Ning Tang, Chen Liu*, A versatile and ultrasensitive electrochemical sensing platform for detection of chlorpromazine based on nitrogen-doped carbon dots/cuprous oxide composite, Nanomaterials, 2020, 10, 1513. (IF=5.076)
[5] Xiao-ying Xu, Jia-hua Liu, Xing Ouyang, Lifeng Cui, Jiaoling Hong, Xiao Meng, Siyin Qin, Chen Liu*, Jiaoning Tang, Da-Zhu Chen*. In-situ temperature regulation of flexible supercapacitors by designing intelligent electrode with microencapsulated phase change materials, Electrochimica Acta, 2020, 334, 135551. (IF=6.091)
2019年
[4] Jiahua Liu,Xiaoying Xu, Jiali Yu, Jiaoling Hong, Chen Liu*, Xing Ouyang, Shuai Lei, Xiao Meng, Jiaoning Tang, Dazhu Chen*, Facile construction of 3D porous carbon nanotubes/polypyrrole and reduced graphene oxide on carbon nanotube fiber for high-performance asymmetric supercapacitors, Electrochimica Acta, 2019, 314: 9-19. (IF=6.091)
[3] Kangqiang He, Samson Ho-Sum Cheng, Chenglin Chen, Chen Liu*, Chengzhu Liao, Yi Xu, Jiaoning Tang, Robert K.Y. Li*, Polyethylene oxide/garnet-type Li6.4La3Zr1.4Nb0.6O12 composite electrolytes with improved electrochemical performance for solid state lithium rechargeable batteries, Composites Science & Technology, 2019, 175: 28-34. (IF=8.528)
[2] Venkata Narayana Palakollu, Tirivashe E. Chiwunz, Chen Liu*, Rajshekhar Karpoormath*, Electrochemical sensitive determination of acetaminophen in pharmaceutical formulations at iron oxide/graphene composite modified electrode, Arabian Journal of Chemistry, 2019, 13: 4350-4357. (IF=5.165)
2018年
[1] Chen Liu, Jie Shen, Chengzhu Liao, Kelvin Wai Kwok Yeung, Sie Chin Tjong*, Novel electrospun polyvinylidene fluoride-graphene oxide-silver nanocomposite membranes with protein and bacterial antifouling characteristics, Express Polymer Letters, 2018, 12(4): 365-382. (IF=4.161)
